Learning models on rooted regular trees with majority update policy: convergence and phase transition
Abstract
We study a learning model in which an agent is stationed at each vertex of Tm, the rooted tree in which each vertex has m children. At any time-step t ∈ N0, they are allowed to select one of two available technologies: B and R. Let the technology chosen by the agent at vertex v∈Tm, at time-step t, be Ct(v). Let \C0(v):v∈Tm\ be i.i.d., where C0(v)=B with probability π0. During epoch t, the agent at v performs an experiment that results in success with probability pB if Ct(v)=B, and with probability pR if Ct(v)=R. If the children of v are v1,…,vm, the agent at v updates their technology to Ct+1(v)=B if the number of successes among all vi with Ct(vi)=B exceeds, strictly, the number of successes among all vj with Ct(vj)=R. If these numbers are equal, then the agent at v sets Ct+1(v)=B with probability 1/2. Else, Ct+1(v)=R. We show that \Ct(v):v∈Tm\ is i.i.d., where Ct(v)=B with probability πt, and \πt\t ∈ N0 converges to a fixed point π of a function gm. For m ≥slant 3, there exists a p(m) ∈ (0,1) such that gm has a unique fixed point, 1/2, when p ≤slant p(m), and three distinct fixed points, of the form α, 1/2 and 1-α, when p > p(m). When m=3, pB=1 and pR ∈ [0,1), we show that g3 has a unique fixed point, 1, when pR < 3-1, two distinct fixed points, one of which is 1, when pR = 3-1, and three distinct fixed points, one of which is 1, when pR > 3-1. When gm has multiple fixed points, we also specify which of these fixed points π equals, depending on π0. For m=2, we describe the behaviour of g3 for all pB and pR.
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